JP2004267290A - Electronic endoscope equipment - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide electronic endoscope equipment allowing an observer to constantly observe an optimal light modulation state without changing over between a peak photometry and the average photometry and suppressing the occurrence of halation when executing an average photometry. <P>SOLUTION: In this electronic endoscope equipment, its light modulation is controlled by a throttle control circuit 19 of a light source device 3 based on the photometry result of a photometry circuit 17. In this case, a gain circuit 34 of the photometry circuit 17 multiplies an output signal of a clip circuit 33 by a gain constant equal to that of the conventional average photometry in a part (the average photometry region 28) corresponding to the circumference part of an imaging range of a CCD 6 and a detection circuit 35 detects the output of the gain circuit 34 at a coefficient equal to the average photometry. When a subject is photographed only in the circumferential part of the imaging range, the light quantity irradiating to the subject becomes a level equal to the conventional average photometry to suppress the halation to the same extent to that of the conventional average photometry. <P>COPYRIGHT: (C)2004,JPO&NCIPI

Description

[0001]
TECHNICAL FIELD OF THE INVENTION
The present invention relates to an improvement in an electronic endoscope apparatus capable of automatically adjusting light.
[0002]
[Prior art]
2. Description of the Related Art In recent years, an electronic endoscope device in which a solid-state imaging device (CCD) is mounted at the distal end of an insertion portion and an observation image captured using the CCD is projected from a video processor to a television monitor has become widespread. 2. Description of the Related Art In an electronic endoscope device, a light source device for enabling a subject to be observed brightly and a light amount for irradiating the subject are automatically adjusted in order to easily observe a body cavity and perform a treatment. (Automatic dimming) function is indispensable.
[0003]
In order to achieve the automatic dimming function, a conventional electronic endoscope device includes a photometric circuit for calculating the brightness of a subject. The light amount is automatically adjusted by controlling the aperture of the light source device according to the brightness calculated by the photometric circuit.
[0004]
Conventionally, as the photometric method, for example, Japanese Patent Publication No. 7-108278 discloses an average photometric method and a peak photometric method. The average photometry method adjusts the amount of light radiated to the subject based on the average value of the reflected light from the subject, while the peak photometry method irradiates the subject based on the peak value of the reflected light from the subject. This adjusts the amount of light to be emitted.
[0005]
The average photometry is an advantageous method when the output of the image sensor is integrated to obtain the average value of the reflected light, and is used when the luminance distribution of the subject is uniform. Also, in the average photometry method, a clipping circuit for clipping a video signal of a predetermined level or more is provided so that a region of interest can be prevented from being darkened by a high-luminance, small-area object such as a treatment tool. Provided.
[0006]
However, when observing a prominent high-luminance subject such as a stomach angle, if the average photometry method is adopted, halation will occur. Therefore, in such a case, a peak photometry method is adopted.
[0007]
The peak photometry is to detect the peak value of the output from the image sensor and control the light amount, and is used when the luminance difference of the subject is large. However, if a treatment tool is used when the peak photometry method is adopted, the entire screen becomes dark, and it becomes difficult to observe the region of interest.
[0008]
That is, the peak photometry method is effective when there is an attention area in a high luminance portion of a subject having a large difference in luminance, and the average photometry method is effective when the luminance distribution is uniform or when observation is performed using a treatment tool.
[0009]
As a related technique, Japanese Patent Application Laid-Open No. 2000-333901 discloses an electronic endoscope having a photometry method in which a central portion has peak photometry and a peripheral portion has average photometry.
[0010]
In the electronic endoscope of this proposal, imaging is performed based on first and second area designation signals for designating the center and the periphery of the imaging range, which are output from the area designation signal output means by the photometry means. By switching the light metering method between the central part and the peripheral part of the range, the light metering result obtained by mitigating the adverse effects of the light metering result of the peripheral part and the light metering result of the central part is obtained. The feature is that the light control level of the subject image is controlled on the basis of this.
[0011]
As a result, an attempt is made to achieve an electronic endoscope apparatus that allows an observer to always perform observation in an optimal dimming state without an observer switching between peak photometry and average photometry.
[0012]
[Patent Document 1]
Japanese Patent Publication No. 7-108278 (pages 3-7, Fig. 1)
[0013]
[Patent Document 1]
JP-A-2000-333901 (pages 5-12, FIG. 1)
[0014]
[Problems to be solved by the invention]
However, in the above-mentioned conventional electronic endoscope apparatus, the observer has to perform observation while switching between the average photometry method and the peak photometry method according to the observation scene, which is inconvenient to use. was there.
[0015]
Further, in the average photometry method in the conventional electronic endoscope apparatus, the integration result is an average value, so that it is set to about 50% of the input level of the integration circuit. In the peak photometry method, the integration result is about 100%. % Is set. Therefore, when a subject having a uniform luminance distribution is photographed, the average result of the photometry is multiplied by approximately twice so that the brightness of the subject in the average photometry and the peak photometry is the same. Therefore, in the conventional average photometry method, the photometry result is increased by this gain, so that the aperture of the light source device is stopped down and the light amount is suppressed.
[0016]
However, in the electronic endoscope apparatus described in Japanese Patent Application Laid-Open No. 2000-333901, the peripheral portion is simply integrated with the time constant of average photometry, and the central portion is integrated with the time constant of peak photometry, and the photometric result is compared with the conventional method. In other words, since the average photometry area is multiplied only by the gain of the conventional average photometry, halation occurs when the subject appears only in the average photometry area in a lumen-shaped subject, for example. Therefore, it is desired to suppress this.
[0017]
Therefore, the present invention has been made in view of the above circumstances, without the need for the observer to switch between peak photometry and average photometry, it is possible to always observe in the optimal dimming state, and when performing average photometry An object of the present invention is to provide an electronic endoscope apparatus capable of suppressing the occurrence of harlation.
[0018]
[Means for Solving the Problems]
In order to achieve the above object, an electronic endoscope apparatus according to a first aspect of the present invention includes: an electronic endoscope including an imaging unit configured to image a subject within a predetermined imaging range; A light source device, an area specifying signal generating means for generating an area specifying signal for specifying a central part and a peripheral part of the imaging range, an amplifying means for amplifying a video signal output from the imaging means, and an output from the amplifying means An integrating means for integrating a video signal to be output for one field with a predetermined time constant, and an integrating means for switching an amplification factor to be amplified by the amplifying means and a time constant to be integrated by the integrating means according to the area designation signal. Detecting means for detecting a video signal output from the camera every one field, and photometry for measuring the brightness of the video signal output from the imaging means based on the detection output of the detecting means. And the step, based on the photometry result of the photometry unit and is characterized by comprising a light quantity control means for controlling the amount of light illuminating the subject by the light source device.
[0019]
An electronic endoscope apparatus according to a second aspect of the present invention includes an electronic endoscope including an imaging unit for imaging a subject in a predetermined imaging range; a light source device for illuminating the subject; First detection means for detecting the average value of the video signal output from the means, second detection means for detecting the peak value of the video signal output from the imaging means, and detection by the second detection means On the basis of the output, a threshold value deciding means for deciding a threshold value at the time of detection processing by the first detecting means, and a threshold value decided by the threshold value deciding means and a detection output by the first detecting means, A comparison control means for switching and controlling a time constant for detection processing by the first detection means based on the result, and a detection output of the first detection means obtained based on the time constant switched by the comparison control means. Base A light meter that measures the brightness of a video signal output from the imager, and a light controller that controls the amount of light that illuminates the subject by the light source device based on the photometric result of the light meter. It is characterized by having.
[0020]
This configuration enables automatic dimming, which makes it easy to observe a subject that causes halation in average photometry such as stomach angle, and treatment tools such as forceps appear in the peripheral part of the endoscope image. Since the section is an average photometric area, the dimming is not affected by the treatment tool, so that automatic dimming that allows easy observation is possible. Further, even when the subject is photographed only in the peripheral portion, the halation of the conventional average photometric level can be suppressed, and when the subject is photographed only in the central portion, the conventional peak photometric level can be observed. Furthermore, halation in the average photometry area can be reduced, and the present invention can be applied to conventional average photometry, so that halation can be reduced.
[0021]
BEST MODE FOR CARRYING OUT THE INVENTION
Hereinafter, embodiments of the present invention will be described with reference to the drawings.
[0022]
First embodiment:
(Constitution)
FIGS. 1 to 3 show a first embodiment of an electronic endoscope apparatus according to the present invention. FIG. 1 is a block diagram showing the entire configuration of the electronic endoscope apparatus according to the present embodiment. 3 is a block diagram showing a specific circuit configuration of the photometric circuit shown in FIG. 3, and FIG. 3 is an explanatory diagram for explaining the operation of the photometric circuit in FIG. An embodiment in which the present invention is applied to an endoscope apparatus of a red (R), green (G), and blue (B) plane sequential type of light source will be described later.
[0023]
As shown in FIG. 1, the electronic endoscope device according to the present embodiment includes an electronic endoscope 1, a video processor 2, a light source device 3, and a television monitor 4.
[0024]
The electronic endoscope 1 has a flexible elongated insertion portion, and a CCD 6 is built in a distal end portion of the insertion portion. An objective lens 5 is provided at the tip of the insertion section so that an optical image from a subject (not shown) is formed on an imaging surface of the CCD 6. The insertion portion is provided with a forceps channel 8 for inserting a treatment tool such as forceps and a light guide 9 for transmitting illumination light from the light source device 3 and irradiating the object with the illumination light.
[0025]
The light source device 3 includes an aperture control circuit 19, an aperture 20, a light source lamp 21, a rotary filter 22, and a brightness control button 23.
[0026]
The light emitted from the light source lamp 21 passes through a rotary filter 22 having red (R), green (G), and blue (B) color transmission filters attached thereto, and passes through a stop 20 to the light guide 9. Be guided. The light guide 9 transmits the incident light to the distal end of the electronic endoscope 1, and irradiates light of each wavelength of red, green, and blue sequentially (in a time series) to a subject (not shown).
[0027]
The CCD driver 7 of the video processor 2 outputs a driving signal for driving the CCD 6. This drive signal is supplied to the CCD 6 via a signal line provided in the insertion section. Thus, the CCD 6 photoelectrically changes the optical image from the subject, and supplies the video signals of the R, G, and B fields to the analog processing circuit 10 of the video processor 2 via the signal lines in the insertion unit. .
[0028]
Although not shown, the analog processing circuit 10 includes a preamplifier for amplifying a CCD output signal, a CDS circuit (correlated double sampling circuit) for performing correlated double sampling processing, and the like. In the analog processing circuit 10, the CCD output signal is amplified by the preamplifier and supplied to the CDS circuit. The CDS circuit double-samples and holds the readout signal from the CCD 6, and then sends the readout signal to the A / D converter 11. Output. In this case, the 1 / f noise and the reset noise included in the output signal of the CCD 6 are removed by the CDS circuit, and a signal having an improved S / N ratio can be obtained.
[0029]
The A / D converter 11 converts an input signal into a digital signal. The output of the A / D converter 12 is supplied to the photometric circuit 17 on the patient circuit side and the digital processing circuit 12 on the secondary circuit side via the isolation unit 13.
[0030]
On the secondary circuit side in the video processor 2, the digital signal processing circuit 12 performs digital signal processing such as OB clamp, white balance, electronic zoom, and image enhancement on the transmitted digital video signal, and performs a synchronization circuit 14. To supply. In this case, the video signal processed by the digital signal processing circuit 12 is a time-series signal of R, G, and B.
[0031]
Although not shown, a synchronizing process needs to be performed to display an image on an observation monitor. Therefore, the synchronizing circuit 14 outputs the output signals (R, G, B time series) of the digital signal processing circuit 12. Signal). That is, the video signals simultaneously read from the synchronization circuit 14 are supplied to the D / A converters 15 corresponding to RGB.
[0032]
The D / A converter 15 converts each input digital signal into an analog signal, and supplies the analog signal to an observation monitor (not shown). Thus, an observation monitor (not shown) displays an image based on the input video signal.
[0033]
On the other hand, on the patient circuit side, the video signal A / D-converted by the A / D converter 11 is also supplied to a photometric circuit 17 for calculating the brightness of the subject. The photometric circuit 17 is controlled by the CPU 24 to calculate the brightness of the subject based on the input signal, and generate a dimming signal for controlling the aperture control circuit 19 of the light source device 3 based on the calculation result. Has become. The dimming signal generated by the photometric circuit 17 is supplied to a D / A converter 18.
[0034]
The D / A converter 18 converts the dimming signal into an analog signal and outputs the analog signal to the aperture control circuit 19 of the light source device 3. The aperture control circuit 19 controls the aperture 20 based on the dimming signal so that the amount of light that has passed through the R, G, and B rotary filters 22 after being emitted from the dimming lamp 21 is reduced. It is being adjusted.
[0035]
In this case, the aperture control circuit 19 controls the brightness of the subject calculated by the photometry circuit 17 and the signal output based on the set value of the brightness control button 23 provided on the front panel (not shown) of the light source device 3. Are compared, if it is determined that the brightness of the subject is higher, the aperture 20 is closed and control is performed so as to reduce the amount of light emitted to the subject. On the other hand, when the aperture control circuit 19 determines that the brightness of the subject is smaller than the signal output from the brightness control button 23, the aperture control circuit 19 opens the aperture 20 to increase the amount of light radiated to the subject. I do.
[0036]
As shown in FIG. 2, the CPU 24 performs photometry of a clip level signal for excluding the brightness of a high-luminance, small-area object such as a treatment tool from a photometry target, and a photometry mode designation signal for instructing a photometry mode. Output to the circuit 17. The clip level signal is determined based on the set value of the brightness control button 23. That is, using the brightness setting button 23, the clip level is increased when the image is set to be bright, and the clip level is decreased when the image is set to be dark.
[0037]
Also, as shown in FIG. 1, the photometric circuit 17 supplies a photometric result to a second light source device (not shown) via a secondary circuit in the video processor 2. In this case, the photometric result obtained by the photometric circuit 17 is P / S converted by the P / S converter 4 and transmitted to the secondary circuit via the isolation unit 13. The photometric result transmitted to the secondary circuit is supplied via a cable (not shown) on the rear panel of the video processor 2 to a second light source device (not shown) connected to the cable. .
[0038]
On the second light source device (not shown) side, the photometric result is D / A-converted in substantially the same manner as in the first light source device 3, and is input to the aperture control circuit of the second light source device. The adjustment of the light is adjusted by controlling the aperture by the aperture control circuit.
[0039]
Next, a specific configuration of the photometric circuit 17 will be described in detail with reference to FIGS.
[0040]
The photometry circuit 17 shown in FIG. 1 includes a gate signal generation circuit 29, a sub-sampling circuit 32, a clip circuit 33, a gain circuit 34, a detection circuit 35, a luminance calculation circuit 36, and a coefficient output circuit 37, as shown in FIG. It is composed of
[0041]
The sub-sampling circuit 32 receives the video output signal from the A / D converter 11 shown in FIG. 1, samples only pixels necessary for photometry from the digital video signal based on the sampling pulse, and supplies the pixels to the clip circuit 33. .
[0042]
The clip operation of the clip circuit 33 is controlled by a gate signal from the gate signal generation circuit 29. The gate signal generation circuit 29 outputs a gate signal corresponding to a position in the imaging range of the CCD 6, for example, a high level (hereinafter abbreviated as “H”) in a portion corresponding to the center of the imaging range (the peak photometry area 27). In this case, a low-level (hereinafter, referred to as “L”) gate signal is output to a portion corresponding to the peripheral portion of the imaging range (the average photometric region 28).
[0043]
Therefore, the clip circuit 33 outputs the video signal (the video signal corresponding to the average photometry area 28 shown in FIG. 3) input at a level based on the clip level setting signal during the period when the gate signal “L” is output. Is output to the gain circuit 34 while the input video signal (the video signal corresponding to the peak photometry area 27 shown in FIG. 3) is clipped during the period when the gate signal “H” is being output. Instead, it is output to the gain circuit 34 as it is.
[0044]
In this case, the gate signal generation circuit 29 always outputs an “L” gate signal when the conventional average photometry mode is selected by the supplied photometry mode designation signal, and the peak photometry mode is selected. In this case, a gate signal of "H" is always output.
[0045]
The gain circuit 34 adjusts the gain by multiplying the video signal, which has been subjected to predetermined processing by the clip circuit 33, by a predetermined gain constant based on the gate signal.
[0046]
That is, in the present embodiment, the gain circuit 34 multiplies the gain by the same gain as in the conventional average photometry during the period when the gate signal outputs “L” corresponding to the average photometry area 28 shown in FIG. To adjust. On the other hand, during the period when the gate signal outputs “H” corresponding to the peak photometry area 27 shown in FIG. 3, the gain is adjusted by multiplying by the same gain as in the conventional peak photometry. In this case, for example, if the gain constant at the time of the conventional peak photometry is one, the gain constant at the time of the peak photometry is also multiplied by about one.
[0047]
For example, the gain constant multiplied by the gain circuit 34 is set so that the output of the detection circuit 35 is about 50% of the input level in the conventional average photometry, and the output of the detection circuit 35 is in the peak photometry. Is set to be about 100% of the input level. For this reason, when the average photometry mode is selected, the output level of the detection circuit 35 is set to be the same at both peak photometry and average photometry when a uniform subject (for example, full screen white) is photographed. It is multiplied by about twice the gain constant (about 1 times at the time of peak photometry). As a result, the output of the detection circuit 35 has the same value, so that the same applies to the photometric result. As a result, the brightness of the endoscope image becomes the same. For such a reason, the gain circuit 35 multiplies the video signal from the clip circuit 33 corresponding to the average photometry area 28 by a preset gain of about twice during the average mode photometry.
[0048]
The output signal of the gain circuit 34 is supplied to a detection circuit 35. The detection circuit 35 is an integration circuit, and integrates the input output signal of the gain circuit 35 based on the gate signal from the gate signal generation circuit 29 and the coefficient from the coefficient output circuit 37. The coefficient output circuit 37 is supplied with a gate signal from the gate signal generation circuit 29. Based on the gate signal, a portion equivalent to the average photometry area 28 is compared with a conventional average photometry time. A coefficient corresponding to an extremely large time constant is output to the detection circuit, and a coefficient corresponding to a relatively small time constant equivalent to that at the time of the conventional peak photometry is used for the portion corresponding to the peak photometry area 27. Output to
[0049]
That is, during the period when the gate signal “L” is output (corresponding to the average photometry area 28), the detection circuit 35 converts the signal input with a relatively large time constant equivalent to that of the conventional average photometry to R, Integration is performed for each of the G and B fields. On the other hand, during the period when the gate signal “H” is output (corresponding to the peak photometry area 27), a signal input with a relatively small time constant equivalent to that of the conventional peak photometry is applied to each of the R, G, and B fields. Is integrated. The output of the detection circuit 35 is supplied to a luminance calculation circuit 36.
[0050]
The brightness calculation circuit 36 calculates the brightness of the subject based on the integrated output of the detection circuit 35 for each of the R, G, and B fields. That is, the brightness calculation circuit 36 calculates the subject brightness by multiplying the integrated outputs of the R, G, and B fields by 0.30, 0.59, and 0.11, respectively, and calculating the subject brightness. Is supplied to the P / S conversion circuit 4 and the D / A converter 18 shown in FIG. In this way, a dimming signal based on the peak photometry result at the center of the imaging range and the average photometry result around the imaging range obtained by the luminance calculation circuit 36 is given to the aperture control circuit 17 on the light source device 3 side.
[0051]
The light source device 3 is provided with a brightness control button 23 for controlling brightness in a plurality of stages on a front panel (not shown). A signal based on the operation of the brightness control button 23 by the observer is supplied to the CPU 24, and the CPU 24 controls the aperture control circuit 19 using the brightness based on the input signal as a set value (not shown). .
[0052]
The aperture control circuit 19 controls the aperture 20 so that the brightness set by the CPU 24 based on the operation of the brightness control button 23 matches the brightness indicated by the dimming signal.
[0053]
Therefore, in the present embodiment, the gain signal equivalent to that of the conventional average photometry is multiplied by the output signal of the clipping circuit 33 for the portion (average photometry area 28) corresponding to the peripheral portion of the imaging range, and the average photometry is used. Since the detection is performed with the same time constant, even when the subject is captured only in the peripheral portion (the average photometry area 28 shown in FIG. 3) of the imaging range of the CCD 6, the output of the photometry result is equivalent to that of the conventional average photometry. Can be obtained, and the amount of light applied to the subject is at the same level as in the conventional average photometry, so that the halation can be suppressed to the same level as the conventional average photometry. Also, when the subject is captured only in the central part of the imaging range of the CCD 6 (the peak photometry area 27 shown in FIG. 3), the detection is performed with the same gain constant as the conventional peak photometry and the same time constant. Therefore, it is possible to observe with the optimal brightness.
[0054]
Note that, in the present embodiment, the above-described circuit block may be configured so that the operation can be switched according to the type of the CCD 6. Further, the gain constant and the coefficient may be finely adjusted so that the luminance signal Y has the same level as the conventional average photometry or peak photometry.
[0055]
(Action)
The operation of the electronic endoscope device configured as described above will be described with reference to FIG.
[0056]
Now, it is assumed that a patient's body cavity is observed using the electronic endoscope apparatus shown in FIG. In this case, the insertion section of the electronic endoscope 1 is inserted into a body cavity (not shown), and illumination light from the light source device 3 is guided into the body cavity via the light guide 9 to illuminate the subject. In the light source device 3, for example, the rotation filter 22 is rotated once every three field periods, and the illumination light of R (red), G (green), and B (blue) is emitted at the field period (1/60 second). .
[0057]
The reflected light from the subject forms an image on the imaging surface of the CCD 6 via the objective lens 5 provided at the tip of the insertion section. As a result, the CCD 6 is controlled by the CCD driver 7 of the video processor 2 to take in an optical image of the subject formed on the imaging surface in a frame-sequential manner and perform photoelectric conversion.
[0058]
The video signal from the CCD 6 is supplied to an analog processing circuit 10 of the video processor 2, where it is amplified by a preamplifier, double-sampled and held by an internal CDS circuit, and A / D-converted. Output to converter 11. Then, the output signal of the analog signal processing circuit 10 is converted into a digital signal by the A / D converter 11 and then supplied to the digital processing circuit 12 via the isolation unit 13.
[0059]
The video signal input to the digital processing circuit 12 is subjected to predetermined digital signal processing such as OB clamp, white balance, electronic zoom, image enhancement, and the like, and is then subjected to RGB synchronization processing by the synchronization circuit 14. After that, the signal is returned to the original analog signal by the D / A converter 15. The output of the D / A converter 15 is output to an observation monitor (not shown).
[0060]
The brightness of the endoscope image displayed on the display screen of the observation monitor (not shown) is automatically adjusted based on the photometry result of the photometry circuit 17 according to the operation of the brightness control button 23.
[0061]
In this case, the gate signal generation circuit 29 in the photometry circuit 17 performs peak photometry in the center of the imaging range and generates a gate signal for performing average photometry in the periphery.
[0062]
That is, the gate signal generation circuit 29 sets the gate of the center (peak photometry area 27) of the "H" gate in the imaging range of the CCD 6 for obtaining the endoscope image 26 displayed on the display screen of the observation monitor shown in FIG. A signal is output, and the peripheral portion (average photometry area 28) outputs an “L” gate signal. The gate signal is supplied to a clip circuit 27, a gain circuit 34, and a coefficient output circuit 37.
[0063]
The clipping circuit 33 clips the video signal input at the level based on the clip level setting signal (the video signal corresponding to the average photometry area 28 shown in FIG. 3) during the period when the gate signal “L” is output. And outputs the same to the gain circuit 34 while clipping the input video signal (the video signal corresponding to the peak photometry area 27 shown in FIG. 3) during the period when the gate signal “H” is being output. Output to the gain circuit 34. Thus, even when a forceps (not shown) is imaged around the imaging range, a high-luminance portion of a CDS output signal by the forceps (not shown) is clipped, and does not affect light control.
[0064]
Further, in the present embodiment, the gain circuit 34 multiplies the same gain as that in the conventional average photometry during the period when the gate signal outputs “L” corresponding to the average photometry area 28 shown in FIG. To adjust the gain. On the other hand, during the period when the gate signal outputs “H” corresponding to the peak photometry area 27 shown in FIG. 3, the gain is adjusted by multiplying by the same gain as in the conventional peak photometry. That is, in the average mode photometry, the gain circuit 35 multiplies the video signal from the clip circuit 33 corresponding to the average photometry area 28 by a preset gain of about twice.
[0065]
The output signal of the gain circuit 34 is supplied to a detection circuit 35, and during the period when the gate signal “L” is being output by the detection circuit 35 (corresponding to the average photometry area 28), the output of the conventional average photometry is used. A signal input with the same relatively large time constant is integrated for each of the R, G, and B fields. On the other hand, during the period when the gate signal “H” is output (corresponding to the peak photometry area 27), a signal input with a relatively small time constant equivalent to that of the conventional peak photometry is applied to each of the R, G, and B fields. Is integrated. Then, the output of the detection circuit 35 is supplied to a luminance calculation circuit 36, and the luminance of the subject is calculated. The luminance calculation circuit 36 outputs the calculation result to the aperture control circuit 19 of the light source device 3 as a dimming signal.
[0066]
On the other hand, the observer operates the brightness control button 23 provided on the light source device 3 to set the brightness of the endoscope image 26 to a desired brightness. A signal based on the operation of the brightness control button 23 is supplied to the CPU 24, and the CPU 24 sets the brightness based on the input signal in the aperture control circuit 19.
[0067]
The aperture control circuit 19 is supplied with a dimming signal from the photometry circuit 17 and controls the aperture 20 so that the brightness based on the dimming signal matches the brightness set in the CPU 24. That is, when the brightness of the subject given by the light control signal is brighter than the set brightness, the aperture control circuit 19 closes the stop 20 to reduce the amount of light irradiated to the subject, and provides the light control signal. If the brightness of the subject is darker than the set brightness, the aperture 20 is opened to increase the amount of light irradiated on the subject.
[0068]
Thereby, the brightness of the subject is automatically adjusted to the brightness based on the operation of the brightness control button 23 by the observer.
[0069]
(effect)
Therefore, according to the present embodiment, a gain constant equivalent to that of the conventional average photometry is multiplied by the output signal of the clipping circuit 33 for the portion (average photometry area 28) corresponding to the peripheral portion of the imaging range, and the average is obtained. Since the detection is performed with the same time constant as that of the photometry, even when the subject is captured only in the periphery of the imaging range of the CCD 6 (the average photometry area 28 shown in FIG. 3), the output of the photometry result is the conventional average photometry. Can be obtained, and the amount of light applied to the subject is at the same level as in the conventional average photometry, so that the halation can be suppressed to the same level as the conventional average photometry.
[0070]
Also, when the subject is captured only in the central part of the imaging range of the CCD 6 (the peak photometry area 27 shown in FIG. 3), the detection is performed with the same gain constant as the conventional peak photometry and the same time constant. Therefore, it is possible to observe with the optimal brightness.
[0071]
Second embodiment:
(Constitution)
4 and 5 show a second embodiment of the electronic endoscope apparatus of the present invention, and FIG. 4 is a block diagram showing a specific circuit configuration of a photometric circuit in the electronic endoscope apparatus of the present embodiment. FIG. 5 and FIG. 5 are characteristic diagrams showing examples of output characteristics corresponding to one field of the detection circuit of FIG. In FIG. 4, the same components as those of the electronic endoscope apparatus according to the first embodiment are denoted by the same reference numerals, and description thereof will be omitted. Only different portions will be described.
[0072]
In the electronic endoscope apparatus according to the present embodiment, a second detection circuit 38, a threshold value determination circuit 39, and a comparison circuit 40 are further provided in the photometric circuit 17 of the electronic endoscope apparatus according to the first embodiment. The difference from the first embodiment is that the photometric circuit 17A is configured.
[0073]
Here, for simplification of the description, a description will be given of the case of average photometry.
[0074]
In the photometry circuit 17A, for example, the photometry mode indicates average photometry, and when the average photometry is performed, the gate signal output from the gate signal generation circuit 29 is always “L”. The operation from the input to the photometric circuit 17A to the output of the sub-sampling circuit 32 operates in the same manner as in the first embodiment.
[0075]
In the present embodiment, the output signal of the sub-sampling circuit 32 is supplied to the clip circuit 33 and the second detection circuit 38. Note that the signal processing operation from the clip circuit 33 to the luminance calculation circuit 36 is the same as in the first embodiment.
[0076]
The second detection circuit 38 detects, for each of the R, G, and B fields, a detection characteristic of the input sampled video signal which is substantially equal to the peak photometry characteristic in order to detect a high-brightness portion of the subject. The signal is detected and supplied to a threshold determination circuit 39 as threshold determination means.
[0077]
The threshold value determination circuit 39 calculates a threshold value of a detection circuit (referred to as a first detection circuit in the present embodiment) 35 for each of RGB fields based on the detection result from the second detection circuit 38. The result is supplied to a comparison circuit 40 as comparison control means.
[0078]
The comparison circuit 40 also receives a detection result detected for each RGB of the first detection circuit 35 and compares the detection result with a threshold value from the threshold value determination circuit 39 for each RGB field. That is, the threshold to be compared is the threshold obtained in the previous field of each of RGB.
[0079]
For example, in the present embodiment, when the comparison circuit 40 determines that the comparison result indicates that the detection result of the first detection circuit 35 is equal to or smaller than the threshold, the comparison circuit 40 determines a coefficient corresponding to a relatively small time constant (for example, An intermediate value between the peak photometry and the average photometry) is supplied from the coefficient output circuit 41 to the detection circuit 35 under the control of the comparison circuit 40. If it is determined that the detection result of the first detection circuit 35 has become equal to or larger than the threshold value, the coefficient corresponding to the relatively large time constant (for example, a value slightly larger than the average photometry coefficient) is controlled by the comparison circuit 40. Thus, the coefficient is supplied from the coefficient output circuit 41 to the first detection circuit 35.
[0080]
An output characteristic example corresponding to one field of the first detection circuit 35 in the present embodiment is shown in FIG. In FIG. 5, the vertical axis indicates the input video signal level, the horizontal axis indicates the number of pixels input to the detection circuit from the start to the end of the detection, and reference numeral 50 indicates a graph indicating the output characteristics of the first detection circuit. Reference numeral 100 indicates a graph showing the output characteristic of the conventional detection circuit.
[0081]
As shown in FIG. 5, in the electronic endoscope apparatus of the present embodiment, a video signal whose video signal level is “100” is input to the first detection circuit 35 and the second detection circuit 38. To be done.
[0082]
In this case, it is assumed that the characteristic of the second detection circuit 38 is substantially peak photometry, and the output video signal level of the second detection circuit 38 is approximately “100”. Assuming that 1/10 of the output is a threshold for switching the coefficient in the coefficient output circuit 41, the threshold determination circuit 39 sets the threshold to "10".
[0083]
Thereafter, the output (detection result) of the first detection circuit 35 is compared with the threshold value “10” by the comparison circuit 40, and the comparison result is used as the detection result of the first detection circuit 35. The comparison circuit 40 supplies a control signal to the coefficient output circuit 41 so that the coefficient output circuit 41 outputs a coefficient corresponding to a relatively small time constant until the comparison result becomes a threshold value of “10”. To control the coefficient output (period (a) shown in FIG. 5).
[0084]
When the comparison result by the comparison circuit 40 becomes a comparison result in which the output (detection result) of the first detection circuit 35 is equal to or larger than the threshold value of “10”, the coefficient output circuit 41 is relatively turned off. The comparison circuit 40 supplies a control signal to the coefficient output circuit 41 to control the output of the coefficient so as to output the coefficient corresponding to the large time constant (period (b) shown in FIG. 5).
[0085]
Here, in the present embodiment, the coefficient output circuit 41 is configured so that the detection result of one field by the first detection circuit 35 is the same as that of the conventional average photometry, as shown in FIG. The period is set so as to output a coefficient corresponding to a time constant whose time constant is slightly larger than that of the conventional average photometry.
The horizontal axis shown in FIG. 5 indicates the number of pixels input to the first detection circuit 35. For example, the total number of pixels input to the first detection circuit 35 from the start of detection to the end of detection is When a video signal having a video signal level of “100” by only ３ is input to the first detection circuit 35 (a portion indicated by ３ in FIG. 5), the present embodiment is executed. The detection result (reference numeral 50) by the first detection circuit 35 of the embodiment is larger than the detection result (reference numeral 100) of the conventional average photometry.
[0086]
That is, since the detection result by the first detection circuit 35 is large, the luminance signal calculated by the luminance calculation circuit 36 is also large, and as a result, the aperture control circuit 19 of the light source device 3 performs drive control in the direction to narrow the aperture 20. I do.
[0087]
Other configurations are substantially the same as those of the first embodiment.
[0088]
Further, in the electronic endoscope apparatus of the present embodiment, the central portion (the peak photometric region 27 shown in FIG. 3) of the imaging range of the CCD 6 is subjected to peak photometry, and the peripheral portion (the average photometric region 28 shown in FIG. 3) is averaged. The photometric circuit 17A of the present embodiment can also be applied to a photometric region of the photometric method (similar to the first embodiment) described above. As a result, halation can be reduced, and The same effect as in the embodiment can be obtained.
[0089]
Note that, in the present embodiment, the operation may be switched in accordance with the type of the CCD 6 in the circuit block described above, as in the first embodiment.
[0090]
(Action)
In the electronic endoscope apparatus according to the present embodiment, in addition to operating in substantially the same manner as the electronic endoscope apparatus according to the first embodiment, the above configuration causes halation with high luminance and a relatively small area. For a small subject, the detection output of the first detection circuit 35 becomes larger than the result of the conventional average photometry, and the output of the photometry circuit 17A becomes large. Thus, the stop 20 of the light source device 3 reduces the amount of light radiated to the subject, so that the halation of the conventional average photometry can be reduced.
[0091]
Also in a photometry system in which the central portion is peak photometry and the peripheral portion is average photometry, halation at the peripheral portion can be reduced by the same operation as described above.
[0092]
(effect)
Therefore, according to the present embodiment, in addition to obtaining the same effects as those of the first embodiment, the conventional average photometry can be performed even for a subject that causes halation with high luminance and a relatively small area. Halation that occurs at the time can be reduced.Also, even in the photometry method where the central part is peak photometry and the peripheral part is average photometry, the halation at the peripheral part can be similarly reduced, so observation with optimal brightness can do.
[0093]
Note that the present invention is not limited to the first and second embodiments, and combinations and applications of the first and second embodiments are also applied to the present invention.
[0094]
[Appendix]
According to the above-described embodiment of the present invention as described in detail above, the following configuration can be obtained.
[0095]
(Additional Item 1) An electronic endoscope including an imaging unit for imaging a subject in a predetermined imaging range,
A light source device for illuminating the subject,
Area designating signal generating means for generating a region designating signal for designating a central part and a peripheral part of the imaging range,
Amplifying means for amplifying a video signal output from the imaging means,
Integrating means for integrating the video signal output from the amplifying means for one field with a predetermined time constant;
Detecting means for detecting a video signal output from the integrating means for each field while switching an amplification factor to be amplified by the amplifying means and a time constant to be integrated by the integrating means according to the area designation signal;
Based on the detection output of the detection means, photometric means for measuring the brightness of the video signal output from the imaging means,
A light amount control unit that controls a light amount for illuminating the subject by the light source device based on a photometry result of the photometry unit;
An electronic endoscope apparatus comprising:
[0096]
(Additional Item 2) An electronic endoscope provided with imaging means for imaging a subject in a predetermined imaging range,
A light source device for illuminating the subject,
First detection means for detecting an average value of a video signal output from the imaging means;
A second detection unit that detects a peak value of a video signal output from the imaging unit;
Threshold value determining means for determining a threshold value at the time of detection processing by the first detection means, based on a detection output by the second detection means;
Comparison control means for comparing the threshold value determined by the threshold value determination means with the detection output by the first detection means, and switching and controlling a time constant for detection processing by the first detection means based on the comparison result;
Based on a detection output of the first detection means obtained based on a time constant switched by the comparison control means, a photometry means for measuring the brightness of a video signal output from the imaging means;
A light amount control unit that controls a light amount for illuminating the subject by the light source device based on a photometry result of the photometry unit;
An electronic endoscope apparatus comprising:
[0097]
(Additional Item 3) An electronic endoscope provided with imaging means for imaging a subject in a predetermined imaging range,
A light source device for illuminating the subject,
Area designation signal generating means for outputting a first area designation signal corresponding to the center of the imaging range and a second area designation signal corresponding to the periphery of the imaging range;
Amplifying means for amplifying a video signal output from the imaging means,
Integrating means for integrating the video signal output from the amplifying means for one field with a predetermined time constant;
The video signal output from the integrating means is detected every field while switching the amplification factor amplified by the amplifying means and the time constant integrated by the integrating means in accordance with the first and second area designation signals. Detection means
The brightness of a video signal output from the imaging means is determined based on the detection output of the detection means while switching the photometry method between the peak photometry method and the average photometry method based on the first and second area designation signals. Metering means for metering
A light amount control unit that controls a light amount for illuminating the subject by the light source device based on a photometry result of the photometry unit;
An electronic endoscope apparatus comprising:
[0098]
(Supplementary Note 4) The detection unit supplies the amplification unit with an amplification factor equivalent to that at the time of average photometry to the amplification unit during a period in which the area designation signal that designates a peripheral portion of the imaging range is output, and amplifies the signal. The electronic device according to claim 1, wherein during the period in which the area designation signal for designating the center of the imaging range is output, an amplification factor equivalent to that at the time of peak photometry is supplied to the amplification means and amplified. Endoscope device.
[0099]
(Supplementary Note 5) The detection means may supply a coefficient corresponding to a relatively large time constant equivalent to that during average photometry to the integration means during a period in which the area designation signal for designating a peripheral portion of the imaging range is output. During the period in which the area designation signal for designating the center of the imaging range is output, a coefficient corresponding to a relatively small time constant equivalent to that during peak photometry is supplied to the integration means and integrated. 2. The electronic endoscope apparatus according to claim 1, wherein:
[0100]
(Additional Item 6) The electronic endoscope apparatus according to Additional Item 1, wherein the photometric means includes the area designation signal generating means, the amplifying means, the integrating means, and the detecting means. .
[0101]
(Additional Item 7) The additional photometric device is characterized in that the photometric unit includes a luminance calculating unit that calculates the luminance of the imaging signal by an operation on the integration result of the integrating unit and outputs the luminance as the photometric result. An electronic endoscope apparatus according to claim 1.
[0102]
(Additional Item 8) The electronic endoscope apparatus according to Additional Item 1, wherein the light amount control unit performs light control by matching brightness set based on an operation of an observer with brightness based on the photometric result. .
[0103]
【The invention's effect】
As described above, according to the present invention, it is not necessary to switch the photometric method according to the observation scene, and an effect is obtained in which optimal light control that can compensate for the disadvantages of the conventional average photometry and peak photometry can be performed. In addition, halation is reduced even in the conventional average photometry, and the effect of performing dimming that is easy to observe can be obtained.
[Brief description of the drawings]
FIG. 1 is a block diagram illustrating a first embodiment of an electronic endoscope apparatus according to the present invention, and illustrating a configuration of an entire electronic endoscope apparatus according to the present embodiment;
FIG. 2 is a block diagram showing a specific circuit configuration of the photometric circuit shown in FIG.
FIG. 3 is an explanatory diagram for explaining the operation of the photometric circuit in FIG. 2;
FIG. 4 is a block diagram showing a second embodiment of the electronic endoscope apparatus of the present invention, and showing a specific circuit configuration of a photometric circuit of the present embodiment.
FIG. 5 is a characteristic diagram illustrating an example of an output characteristic corresponding to one field of the detection circuit of FIG. 4;
[Explanation of symbols]
1. Electronic endoscope,
2. Video processor,
3. Light source device
6 ... CCD,
8 ... forceps channel,
9 ... Light guide,
10. Analog processing circuit,
11 A / D converter,
12 Digital processing circuit,
13 ... Isolation part,
14 ... Synchronization circuit,
15, 18 ... D / A converter,
17, 17A: photometric circuit,
19 ... Aperture control circuit,
20 ... Aperture,
21 ... light source lamp,
22 ... Rotating filter,
23 ... Brightness control button
24 ... CPU,
29 gate signal generation circuit
32 ... subsampling circuit,
33: clip circuit,
34 ... Gain circuit,
35 detection circuit (first detection circuit)
36 ... luminance calculation circuit
37, 41 ... coefficient output circuit,
38 second detection circuit,
39: threshold value determination circuit,
40 ... Comparison circuit.

Claims (2)

An electronic endoscope including an imaging unit for imaging a subject in a predetermined imaging range,
A light source device for illuminating the subject,
Area designating signal generating means for generating a region designating signal for designating a central part and a peripheral part of the imaging range,
Amplifying means for amplifying a video signal output from the imaging means,
Integrating means for integrating the video signal output from the amplifying means for one field with a predetermined time constant;
Detecting means for detecting a video signal output from the integrating means for each field while switching an amplification factor to be amplified by the amplifying means and a time constant to be integrated by the integrating means according to the area designation signal;
Based on the detection output of the detection means, photometric means for measuring the brightness of the video signal output from the imaging means,
A light amount control unit that controls a light amount for illuminating the subject by the light source device based on a photometry result of the photometry unit;
An electronic endoscope apparatus comprising: An electronic endoscope including an imaging unit for imaging a subject in a predetermined imaging range,
A light source device for illuminating the subject,
First detection means for detecting an average value of a video signal output from the imaging means;
A second detection unit that detects a peak value of a video signal output from the imaging unit;
Threshold value determining means for determining a threshold value at the time of detection processing by the first detection means, based on a detection output by the second detection means;
Comparison control means for comparing the threshold value determined by the threshold value determination means with the detection output by the first detection means, and switching and controlling a time constant for detection processing by the first detection means based on the comparison result;
Based on a detection output of the first detection means obtained based on a time constant switched by the comparison control means, a photometry means for measuring the brightness of a video signal output from the imaging means;
A light amount control unit that controls a light amount for illuminating the subject by the light source device based on a photometry result of the photometry unit;
An electronic endoscope apparatus comprising:

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